JP2005163847A - Method of manufacturing vacuum heat insulation material and method of manufacturing thermal insulation body - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an epoch-making method of manufacturing a vacuum thermal insulation material and a method of manufacturing a thermal insulation body capable of developing such an acting effect that could have never hitherto been produced before. <P>SOLUTION: In this method of manufacturing the plate-like vacuum thermal insulation material formed of an outer plate body 1 and an inner plate body 2 and having a vacuum layer 3 created by vacuum heating between the outer plate part and the inner plate part, a heat resistant inclusion 4 capable of withstanding heating in the vacuum heating is disposed in a space S formed of the outer plate body 1 and the inner plate body 2, and the space S is evacuated by the vacuum heating. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a method for manufacturing a vacuum heat insulating material and a method for manufacturing a heat insulating container.

  Conventionally, a vacuum double heat insulation structure in which a vacuum layer is formed between the outer wall and the inner wall is generally used as the peripheral wall structure of a heat insulating container such as a water bottle or a pot. A vacuum is formed between the outer wall and the inner wall. In consideration of the influence of atmospheric pressure generated by the above, the container having the peripheral wall of these vacuum double heat insulating structures is exclusively cylindrical.

  That is, when the cylindrical container 20 is used as shown in FIG. 11 (particularly in the case of a small diameter), the atmospheric pressure (arrow P in FIG. 11) is supported by the entire peripheral wall constituting the container 20. Therefore, the outer wall 21 is not recessed and does not come into contact with the inner wall 22. However, when the rectangular tube-shaped container 30 is used as shown in FIG. 12, the atmospheric pressure (the arrow in FIG. P) is supported by each peripheral wall constituting the container 30 alone, so that the central portion of the outer wall 31 constituting each peripheral wall is recessed inward and abuts the inner wall 32 (supports atmospheric pressure on a flat surface). It is easy to dent if it is a shape to be)), it looks bad and loses its value as a product, of course, it becomes fatal as a heat insulation structure.

  However, the rectangular tube-shaped container has better volumetric efficiency (storage efficiency when storing the container itself in another storage space and storage efficiency when storing liquid or the like in the container) than the cylindrical container. Therefore, there is also a desire to obtain a rectangular tube-shaped container (box) having a wall portion of a vacuum double heat insulating structure.

  Therefore, conventionally, a plate-like vacuum heat insulating material (hereinafter referred to as a conventional example) that can realize a rectangular tube-shaped container having a wall portion of this vacuum double heat insulating structure has been proposed.

  This conventional example is composed of an outer plate body and an inner plate body, and is a plate-like one provided with a vacuum layer created by a vacuum heat treatment between the two. It is manufactured by placing glass fibers in the space to be formed and vacuum-treating the space.

  Therefore, in the conventional example, since the glass fiber is interposed in the space between the outer plate body and the inner plate body, even if the space is evacuated, the outer plate body and the inner plate body are prevented from being dented inward by atmospheric pressure, Therefore, a plate-shaped vacuum heat insulating material that is not deformed by atmospheric pressure is obtained, and a rectangular tube-shaped container can be manufactured by joining a plurality of the plate-shaped vacuum heat insulating materials.

  However, the applicant of the present invention made various trials on this conventional example and confirmed that there were the following problems.

  That is, in the conventional example, glass fiber is adopted as an object interposed in the space formed by the outer plate body and the inner plate body, but this glass fiber can withstand vacuum processing at high temperatures in a vacuum heating furnace. (The heat distortion temperature is about 300 to less than 500 ° C.) Therefore, the conventional example has to be a vacuum treatment at room temperature where the degree of vacuum does not increase. Therefore, the conventional example has insufficient heat insulation, and cannot be applied to places where heat insulation is strongly required.Furthermore, high-temperature heat insulation is required because glass fibers cannot be said to have good heat resistance. From the above, the conventional example has a narrow application range, such as being inapplicable to a heat insulating container.

  As a result of repeating various experiments and researches, the present applicant has developed a revolutionary vacuum insulation material manufacturing method and a heat insulating container manufacturing method that exhibit unprecedented effects. .

  The gist of the present invention will be described with reference to the accompanying drawings.

  A method of manufacturing a plate-shaped vacuum heat insulating material, which is composed of an outer plate body 1 and an inner plate body 2 and is provided with a vacuum layer 3 created by vacuum heat treatment between the outer plate body 1 and the outer plate body 1 A heat insulating inclusion 4 capable of withstanding the heat of the vacuum heat treatment is disposed in a space S formed by the inner plate body 2 and the space S is evacuated by the vacuum heat treatment. The present invention relates to a method for manufacturing a material.

  Moreover, in the manufacturing method of the vacuum heat insulating material according to claim 1, the space S formed by the outer plate body 1 and the inner plate body 2 is vacuum-heated at a high temperature of about 500 ° C. or higher to make a vacuum. It concerns on the manufacturing method of the vacuum heat insulating material characterized by these.

  Moreover, in the manufacturing method of the vacuum heat insulating material of any one of Claim 1, 2, the heat resistant inclusion 4 which consists of ceramics as the said heat resistant inclusion 4 was employ | adopted, The vacuum heat insulating material characterized by the above-mentioned. It relates to a manufacturing method.

  Moreover, in the manufacturing method of the vacuum heat insulating material of any one of Claims 1-3, it concerns on the manufacturing method of the vacuum heat insulating material characterized by making the said heat resistant inclusion 4 into plate shape. .

  Moreover, in the manufacturing method of the vacuum heat insulating material of any one of Claims 1-4, in any one or both of the inner surface of the outer plate body 1, the inner surface of the inner plate body 2, copper, aluminum, silver, The present invention relates to a method for manufacturing a vacuum heat insulating material, in which a heat radiation layer 6 made of a heat radiation material such as nickel is formed.

  Further, a heat insulating container formed by combining a plurality of plate-like vacuum heat insulating materials 5 each having a vacuum layer 3 formed by vacuum heat treatment between the outer plate body 1 and the inner plate body 2. In this manufacturing method, the space S formed by the outer plate body 1 and the inner plate body 2 is provided with a heat-resistant inclusion 4 that can withstand the heating of the vacuum heating treatment, and the space S is vacuum heated. The present invention relates to a method for producing a heat insulating container, characterized in that a vacuum is formed by treatment.

  Further, it is a method for manufacturing a heat insulating container composed of a wall of a vacuum heat insulating structure, which is composed of an outer plate body 1 and an inner plate body 2 and provided with a vacuum layer 3 created by vacuum heat treatment therebetween. Then, the space S formed by the outer plate body 1 and the inner plate body 2 is provided with a heat-resistant inclusion 4 that can withstand the heating of the vacuum heat treatment, and the space S is vacuum-heated to be evacuated. The present invention relates to a method for producing a heat insulating container.

  Since the present invention has been described above, a plate-like vacuum heat insulating material having high heat insulating properties by vacuum heat treatment can be obtained, such as an innovative vacuum heat insulating material that exhibits unprecedented effects. It becomes a manufacturing method and a manufacturing method of a heat insulation container.

  BEST MODE FOR CARRYING OUT THE INVENTION The best mode of the present invention considered to be suitable will be briefly described with reference to the drawings, showing the effects of the present invention.

  In the present invention, the space S formed by the outer plate body 1 and the inner plate body 2 is provided with a heat-resistant inclusion 4 capable of withstanding the heat of the vacuum heat treatment, and the space S is vacuum-heated to be evacuated. To do.

  In particular, when vacuum heat treatment with a high degree of vacuum that is easily affected by atmospheric pressure is performed, the outer plate 1 and the inner plate 2 may be deformed and stuck. Since inclusions exist in the space S formed by the outer plate body 1 and the inner plate body 2, the outer plate body 1 and the inner plate body 2 are reliably prevented from sticking to each other.

  Furthermore, since this inclusion is a heat-resistant inclusion 4 that can withstand the heat of the vacuum insulation treatment, the degree of vacuum in the space S can be increased, and further, it can be applied to usage scenes that require high-temperature insulation. It becomes.

  Therefore, unlike the conventional example described above, the degree of vacuum is in a very high state, so that it becomes a vacuum heat insulating material having an extremely excellent high heat insulating property and can be widely applied to other products requiring high heat insulating properties. Thus, the commercial value of the plate-like vacuum heat insulating material can be dramatically improved.

  Specific embodiments of the present invention will be described with reference to the drawings.

  This embodiment is a method for manufacturing a plate-like vacuum heat insulating material 5 having a vacuum layer 3 inside.

  Specifically, the plate-like vacuum heat insulating material 5 is composed of an outer plate body 1 and an inner plate body 2, and a heat-resistant inclusion 4 is interposed between the outer plate body 1 and the inner plate body 2. Further, a heat radiation layer 6 is formed between the outer plate 1 and the heat-resistant inclusions 4 and between the inner plate 2 and the heat-resistant inclusions 4.

  As shown in FIG. 1, the outer plate body 1 and the inner plate body 2 are formed by forming appropriate metal (stainless steel) members into a rectangular plate shape, and the outer plate body 1 becomes the inner plate body 2. The surface area is slightly larger than that.

  Further, the outer plate body 1 and the inner plate body 2 have rising walls 1a and 2a formed at the peripheral edges, respectively, and when the outer plate body 1 and the inner plate body 2 are superposed on each other, the inner plate body 2 is placed inside the rising wall 1a of the outer plate body 1. The rising wall 2a is in a state of being arranged, so that a space S surrounded by the rising wall 2a of the inner plate body 2 is formed between the outer plate body 1 and the inner plate body 2. ing.

  In addition, a gap is provided between the rising wall 1a of the outer plate 1 and the rising wall 2a of the inner plate 2, and this gap is the air vent 7 when performing vacuum processing. Is configured to function as

  As shown in FIG. 1, the heat-resistant inclusion 4 is a ceramic plate formed in a square plate shape.

  In this example, “Iso wool (trademark) 1260 blanket” manufactured by Isolite Industry Co., Ltd. is used as the ceramic, which has heat resistance up to 1260 ° C., and is a vacuum heating furnace used in this example. It can withstand high temperatures (high temperatures up to about 1100 ° C), and it has excellent heat insulation properties such as being used for the heat insulation structure of the wall that constitutes the vacuum heating furnace. doing. In addition, the ceramic (fiber) is lightweight and flexible, and has excellent handling properties.

  Further, the thickness of the heat-resistant inclusion 4 is such that when the heat-resistant inclusion 4 is disposed in the space S between the outer plate body 1 and the inner plate body 2, the outer plate body 1 and the inner plate body 2 respectively. The thickness is set so as to be in contact with or close to the inner surface.

  As shown in FIG. 1, the heat radiation layer 6 is formed by forming copper as a heat radiation material into a rectangular sheet (foil shape), and this copper foil 6 is formed between the outer plate 1 and the heat-resistant inclusion 4. And it is comprised so that it may arrange | position between the inner-plate body 2 and the heat-resistant inclusions 4. FIG. The heat radiating material for forming the heat radiating layer 6 is not limited to copper, but may be gold, aluminum, silver, nickel, for example, and heat radiation is applied to the inner surface of the outer plate 1 and the inner surface of the inner plate 2. The heat radiation layer 6 may be formed by plating the material.

  The manufacturing method of the plate-shaped vacuum heat insulating material 5 which consists of the above structure is demonstrated.

  First, as shown in FIG. 1, in the state where the copper foil 6 is arranged on the inner surfaces of the outer plate body 1 and the inner plate body 2, the heat-resistant inclusions are formed in the space S between the outer plate body 1 and the inner plate body 2. 4 is disposed in a sandwiched state. At this time, a gas absorbent 8 (getter material) that absorbs gas generated from each of the outer plate body 1 and the inner plate body 2 during the vacuum heat treatment is also disposed, and the gas absorbent 8 is about 500 ° C. or higher. The gas absorbent 8 that exhibits its function at a high temperature is employed.

  Subsequently, as shown in FIG. 2, the brazing material 9 is disposed so that a part of the air vent 7 is closed (FIG. 3 is a cross-sectional view taken along the line AA of FIG. 2, and FIG. 4 is a view of B of FIG. -B sectional view). In this embodiment, a brazing material 9 that melts at about 1000 ° C. is used.

  Subsequently, vacuum heat treatment is performed in a vacuum heating furnace.

  Specifically, when the temperature in the vacuum heating furnace is increased to reach about 500 ° C., the gas absorbent 8 acts to absorb the gas generated from the outer plate 1 and the inner plate 2, The temperature is raised while venting air, and when the temperature reaches about 1000 ° C., the brazing material 9 is melted, and the melted brazing material 9 flows into the air vent 7 to block all of the air vent 7 (FIG. 5). , 6).

  Thereafter, the brazing material 9 is solidified by lowering the temperature, whereby the air vent 7 is sealed and the vacuum heat insulating material 5 having a vacuum space S is obtained.

  Incidentally, as a method of melting and solidifying the brazing material 9, in addition to the above-described case, for example, as shown in FIGS. The end of the rising wall 2a is disposed in the concave groove 1b, and the brazing material 9 is disposed so that a part of the air vent 7 formed by the concave groove 1b and the rising wall 2a is closed. It is good also as a structure which the molten brazing material 9 flows in into the ditch | groove 1b, and blocks the whole air vent part 7 by heating in a state.

  When vacuum heat treatment with a high degree of vacuum is performed using the vacuum heating furnace described above, the outer plate body 1 and the inner plate body 2 tend to deform due to the influence of atmospheric pressure. Since the heat-resistant inclusion 4 that can withstand the heat of the vacuum heat treatment is interposed in the space S formed by the body 2, the deformation of the outer plate body 1 and the inner plate body 2 is prevented. It is also reliably prevented that the inner plate body 2 comes into contact.

  The plate-like vacuum heat insulating material 5 obtained as described above is combined (for example, welded) as shown in FIG. 9 so that it can be attached to a wall such as a water bottle, a pot, a microwave oven, a refrigerator, etc. A vacuum double heat insulating container requiring a heat insulating structure can be produced, and since the space S of the vacuum heat insulating material 5 becomes a vacuum, an excellent heat insulating effect can be obtained, and the heat resistant inclusion 4 itself. Is a ceramic having heat resistance, and is particularly suitable for use at high temperatures.

  Further, according to the technique of this embodiment, as shown in FIG. 10, a rectangular tube-shaped inner plate body 2 is disposed in a rectangular tube-shaped outer plate body 1 at a predetermined interval, and the space S is heat resistant. The present invention can also be applied to the case of obtaining a rectangular tube-shaped vacuum double heat insulating container produced by performing a vacuum heat treatment in a state in which the inclusion 4 is disposed.

  Also, even if it is a cylindrical vacuum double insulated container, it may be affected by atmospheric pressure. For example, the bottom of large containers such as large pots (insulated cooking pots) and drum cans are affected by atmospheric pressure. Conventionally, measures have been taken such as forming ribs on the plate material constituting the bottom portion, but the manufacturing efficiency is poor. Therefore, the heat-resistant inclusion 4 is placed in the space S of the cylindrical container. By performing the vacuum heat treatment in the disposed state, a cylindrical vacuum double heat insulating container having a good vacuum heat insulating structure can be easily obtained.

  Since the present embodiment is configured as described above, unlike the conventional example described above, the degree of vacuum is in a very high state, so that the vacuum heat insulating material 5 having extremely excellent high heat insulating properties is obtained. The commercial value of the plate-like vacuum heat insulating material 5 can be drastically improved, such as being widely applicable to other required products.

  As an application example to other products, it is considered preferable to apply the vacuum heat insulating material 5 obtained by the present invention to, for example, a wall portion constituting the microwave oven.

  Specifically, conventionally, since the thickness of the wall portion of the microwave oven is determined by the thickness of the heat insulating material disposed in the wall portion, it is extremely difficult to reduce the size and weight. Since the vacuum heat insulating material 5 obtained by the manufacturing method has excellent high heat insulating properties even if it is thin, the wall portion of the microwave oven can be drastically thinned to achieve a reduction in size and weight. In addition, when applied to other products, it exhibits excellent operational effects in addition to the heat insulating effect.

  In this embodiment, the space S formed by the outer plate body 1 and the inner plate body 2 is vacuum-heated at a high temperature of about 500 ° C. or higher to be evacuated. The high temperature is a temperature at which a good degree of vacuum that can achieve high heat insulation is obtained, and is a temperature at which the gas absorbent 8 and the brazing material 9 act when the temperature is about 500 ° C. or higher.

  Moreover, since the heat-resistant inclusion 4 which consists of ceramics was employ | adopted as the heat-resistant inclusion 4 in a present Example, the vacuum heat processing can be performed and the plate-shaped vacuum heat insulating material 5 which has the outstanding high heat insulation property can be performed. Is certainly obtained.

  Further, in this embodiment, since the heat-resistant inclusions 4 are formed in a plate shape, the outer plate body 1 and the inner plate body 2 to be deformed can be surely supported by vacuum treatment, and In addition, excellent high heat insulating properties are exhibited over the entire vacuum heat insulating material 5.

  Further, in this embodiment, since the heat radiation layer 6 made of the heat radiation material is formed on both the inner surface of the outer plate body 1 and the inner surface of the inner plate body 2, it is possible to provide even better heat insulation.

  Note that the present invention is not limited to this embodiment, and the specific configuration of each component can be designed as appropriate.

It is a disassembled perspective view of the vacuum heat insulating material which concerns on a present Example. It is a perspective view which shows a present Example. It is sectional drawing explaining the principal part which concerns on a present Example. It is sectional drawing explaining the principal part which concerns on a present Example. It is a perspective view of the vacuum heat insulating material which concerns on a present Example. It is sectional drawing explaining the principal part which concerns on a present Example. It is sectional drawing explaining another type of the vacuum heat insulating material which concerns on a present Example. It is sectional drawing explaining another type of the vacuum heat insulating material which concerns on a present Example. It is explanatory drawing of the heat insulation container manufactured by the manufacturing method which concerns on a present Example. It is explanatory drawing of the heat insulation container manufactured by the manufacturing method which concerns on a present Example. It is explanatory drawing which shows a prior art example. It is explanatory drawing which shows a prior art example.

Explanation of symbols

S space 1 outer plate body 2 inner plate body 3 vacuum layer 4 heat-resistant inclusion 5 vacuum heat insulating material 6 heat radiation layer

Claims (7)

  A method of manufacturing a plate-like vacuum heat insulating material, which is composed of an outer plate body and an inner plate body, and is provided with a vacuum layer created by vacuum heat treatment between the outer plate body and the inner plate body, A heat insulating inclusion capable of withstanding the heat of the vacuum heat treatment is disposed in the space formed by the above, and the space is evacuated by the vacuum heat treatment.   2. The method of manufacturing a vacuum heat insulating material according to claim 1, wherein the space formed by the outer plate body and the inner plate body is vacuum-heated by a vacuum heat treatment at a high temperature of about 500 ° C. or higher. A method of manufacturing a heat insulating material.   The method for manufacturing a vacuum heat insulating material according to any one of claims 1 and 2, wherein a heat-resistant inclusion made of ceramic is employed as the heat-resistant inclusion.   The manufacturing method of the vacuum heat insulating material of any one of Claims 1-3 WHEREIN: The said heat resistant inclusion was made into plate shape.   In the manufacturing method of the vacuum heat insulating material of any one of Claims 1-4, heat, such as copper, aluminum, silver, nickel, is applied to either one or both of the inner surface of the outer plate body and the inner surface of the inner plate body. A method for producing a vacuum heat insulating material, wherein a heat radiation layer made of a radiation material is formed.   A method for manufacturing a heat insulating container formed by combining a plurality of plate-like vacuum heat insulating materials, each of which is composed of an outer plate body and an inner plate body and provided with a vacuum layer created by vacuum heat treatment between the two. A heat insulation characterized by disposing a heat-resistant inclusion capable of withstanding the heat of the vacuum heat treatment in a space formed by the outer plate body and the inner plate body, and vacuuming the space by the vacuum heat treatment. A method for producing a container.   A method for producing a heat insulating container comprising a wall of a vacuum heat insulating structure, which is composed of an outer plate body and an inner plate body, and is provided with a vacuum layer created by vacuum heat treatment between the outer plate body and the outer plate. A heat-insulating container characterized in that a heat-resistant inclusion capable of withstanding the heat of the vacuum heat treatment is disposed in a space formed by the body and the inner plate body, and the space is subjected to vacuum heat treatment to form a vacuum Method.

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